KR101797392B1 - Floating type multi-purpose platform system for shallow water - Google Patents

Abstract

The present invention relates to a floating type platform system, installed in coastal waters within 200 m of the water depth. More specifically, the present invention relates to the multipurpose floating type platform for coastal waters, connecting multiple standardized modules to enable an offshore facility of various sizes and various shapes to be installed and operated.

Description

[0001] Description [0002] Floating type multi-purpose platform system for shallow water [0003]

The present invention relates to a floating platform system installed in an offshore of a depth of 200m or less, and more particularly, to a multi-purpose floating platform system for an offshore system configured to connect various standardized modules to install and operate marine facilities of various sizes and shapes will be.

In recent years, not only gas production but gas facilities such as oil terminal, airport and passenger terminal for logistics and passenger transportation, marine power generation facilities such as wind power generation, wave power generation and tidal power generation, villas for tourism and leisure, Demand for marine platforms for various uses is increasing.

In general, shallow shallow waters have fixed and semi-fixed platforms, while deep waters have floating platforms.

However, since fixed platforms are vulnerable to earthquakes and tsunamis, there is a growing demand for floating platforms in the offshore area.

This floating platform for offshore is the key technology to make a floating base that can be placed on buildings and various facilities.

Floating platforms close to the shore are required to act as breakwaters. Unlike float platforms, which float over the surface of water installed in deep water, offshore platforms require floating floors that are immersed in water .

In addition, floating platforms installed in shallow waters are required to have various types of structures depending on their applications, so that they must have an infrastructure capable of ensuring diversity and expandability of forms.

Such an offshore floating platform base is required to have a fixing technique capable of minimizing left / right / up / down movements of environmental loads such as tides, waves, tides, and winds.

Korean Unexamined Patent Application Publication No. 10-2001-0006326, "Subtype Pants Platform &

The present invention relates to a method for constructing a floating platform in various sizes and shapes by assembling square-shaped standardized modules according to a designed size and shape to provide a gas terminal, a floating airport or passenger terminal, a marine energy generating facility, It is an object of the present invention to provide a stable, multi-purpose floating platform system for use in marine facilities of various sizes and shapes, including hotels, marine cities, and by restricting horizontal and vertical movements.

In order to achieve the above object, an offshore multi-purpose floating platform system according to the present invention includes an upper flat plate 101 in a rectangular plane shape, a pontoon A square module 110 constituted by a neighboring module and fastening means and constituting a platform 100, and a fixture 103 formed at a predetermined interval on the outside of the pontoon 102; And fixing means coupled to the square module 110 and the bottom surface to limit the vertical and horizontal movements of the square module 110; .

At this time, an upper flat plate 101 having the same size as that of the rectangular module 110 is formed, and an upper flat plate 101 having an eyepiece portion 131 formed at the corner of the upper flat plate 101 is formed A pontoon 102 for providing buoyancy is formed at a lower portion of the upper plate 101 and a fixing hole 103 for fixing the fixing means at predetermined intervals is formed on the outer side of the pontoons 102, And a ship eyepiece module 130 that is connected to a side surface of the module 110 and is fastened by fastening means so that the ship can beretail into the eyepiece portion 131.

An upper plate 101 having a rectangular flat plate 101 of the same size as that of the rectangular module 110 and an upper plate 101 having an inclined surface 121 whose one side is inclined downward outward, A pontoon 102 for providing buoyancy is formed at a lower portion of the upper plate 101 and a fastener 103 for fastening the fastening means at a predetermined interval to the outside of the pontoons 102, And an aircraft eyepiece module 120 coupled to the square module 110 or the ship eyepiece module 120 by fastening means so as to allow the amphibian to beret on the slope 121.

At this time, the interior of the pontoons 102 is divided into a plurality of compartments, and the compartments are formed of storage or ballast tanks.

In addition, the upper plate 101 is formed in a rectangular shape having a width to height or a width to height ratio of 1: 2.

The rim of the pontoons 102 is formed to be spaced apart from the lower surface of the upper plate 101 by a predetermined distance inward from the rim of the upper plate 101.

The fixing means includes a suction anchor 104 fixed to the sea floor, an upper tension riser 105 vertically connecting the suction anchor 104 and the fixture 103, and one side fixed to the sea floor And a mooring line 106 connecting the other side to the fixing hole 103 of the platform 100 so as to be inclined so as to limit the vertical and horizontal movements of the platform 100 by submerging the platform 100 to the load draft at the seawater .

Alternatively, the fixing means may include a suction anchor 104 fixed to the sea bed, an upper tension riser 105 vertically connecting the suction anchor 104 and the fixing member 103, It is also possible to configure the platform 100 to be submerged in the seawater at the load draft to limit the vertical and horizontal movement of the platform 100 by installing the installed thruster 107.

In the offshore multi-purpose floating platform system of the present invention constructed as described above, the standardized square modules are connected to each other and expanded and tightened, thereby not only the gas production but also the gas terminal, the floating airport and passenger terminal, the marine power generation facility, , Marine cities, and other marine facilities of various sizes and shapes.

In addition, the offshore multi-purpose floating platform system according to the present invention can significantly reduce the damage of tsunami and can function as a breakwater when installed close to the shore because it is a floating platform based on water.

In addition, a wave generator can be installed on the pontoon side of the sea level.

In addition, the area of the pontoon can be adjusted to the displacement to cope with various loads from heavy to light weight. By forming a space between the pontoon and the pontoon of the module, Alternatively, a tidal generator may be installed and operated.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a planar perspective view of a square module of the present invention.
2 is a bottom perspective view showing a square module of the present invention.
3 is a side view showing a square module of the present invention.
4 is a perspective view showing an aircraft eyepiece module of the present invention.
5 is a bottom view of the aircraft eyepiece module of the present invention.
6 is a perspective view showing a ship eyepiece module of the present invention.
7 is a bottom view of the ship eyepiece module of the present invention.
8 is a side view showing a state in which the module is tightened and expanded.
Figure 9 shows a floating platform constructed by fastening two square modules.
Figure 10 shows a floating platform constructed by fastening two ship eyepiece modules.
11 shows a floating platform constructed by fastening a square module and an aircraft eyepiece module.
12 is a view showing a state in which the floating platform of the present invention is installed on the sea floor;
Figure 13 shows a floating platform composed only of square modules.
Figure 14 shows a floating platform constructed by fastening each module.
15 illustrates a large floating platform constructed by combining and joining multiple modules.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, the present invention will be described in detail with reference to preferred embodiments of the present invention and the accompanying drawings, wherein like reference numerals refer to like elements.

It is to be understood that when an element is referred to as being "comprising" another element in the description of the invention or in the claims, it is not to be construed as being limited to only that element, And the like.

The floating platform according to the present invention consists of standardized modules fastened and extended. The standardized module used in the floating platform 100 of the present invention is composed of three modules.

1 to 3 are diagrams showing the square module 110. FIG.

1 to 3, the rectangular module 110 includes a rectangular upper flat plate 101, a pontoon 102 fastened to the lower portion of the upper flat plate 101, And a fixing member 103 formed thereon.

The upper flat plate 110 constituting the square module 110 is widely and flatly formed so that various buildings and power generating facilities can be installed.

A pontoon 102 is provided at a lower portion of the upper plate 101 so as to contact the upper plate 101. The pontoons 102 are submerged in water and provide buoyancy to the upper plate 101.

The inside of the pontoon 102 is formed with an empty space for providing buoyancy. The inside of the pontoon 102 may be formed as an empty space. However, the inside space of the pontoon 102 may be divided into a plurality of compartments (not shown) And each of the compartments is constituted by an oil / gas reservoir or a ballast tank so that the level of the upper plate 101 can be constantly maintained regardless of the load change using the ballast tank.

A predetermined number of fasteners 103 are provided on the outside of the pontoons 102 so that the rectangular modules 110 are fastened to the upper tension riser when installed in the ocean.

The airborne eyepiece module 120 shown in FIG. 4 and FIG. 5 together with the rectangular module 110 configured as described above can be coupled and extended together with the rectangular module 110 to form the floating platform 100.

4 and 5, the aircraft eyepiece module 120 is formed with an upper flat plate 101 having a sloped surface 121 inclined to one side, and a pontoon 102 And a predetermined number of fasteners 103 are formed on the outside of the pontoons 102.

The aircraft eyepiece module 120 configured as described above is a berthing facility for an amphibian, especially designed for being able to leave and land on both sides of an aircraft.

The inclined surface 121 formed on the upper surface of the aircraft eyepiece module 120 is configured to be inclined in one direction of the upper surface plate 101. When the platform including the aircraft eyepiece module 120 is installed on the sea, The part is submerged below sea level.

The amphibious airplane landed on the sea so that the passenger or the article can be lowered by riding on the inclined surface 121 of the avid eyepiece module 120 or the amphibious plane can berth in the avid eyepiece module 120 to load the passenger or the commodity .

The pontoons 102 are installed at the lower portion of the aircraft eyepiece module 120 to provide buoyancy to the eyepiece eyepiece module 120. The inside of the pontoons 102 is entirely filled with voids However, the internal space of the pontoon 102 may be divided into a plurality of compartments (not shown), and the respective formations may be constituted by oil / gas reservoirs or ballast tanks, It is possible to configure the airplane eyepiece module 120 to keep the horizontal level constant.

Further, the aircraft eyepiece module 120 is fixed to the ocean by fastening the fastener 103 formed on the outside of the pontoons 102 of the eyepiece eyepiece module 120 with the upper tension riser.

The above-described aircraft eyepiece module 120 is for bidding an amphibious aircraft on a platform 100 constructed based on the above-described rectangular module 110 and is provided with a ship eyepiece module 130 It is preferable to configure the platform 100. [

6 and 7, the ship's eyepiece module 130 installed in the platform 100 according to the present invention is formed with an upper plate 101 and a pontoon (not shown) 102 and fasteners 103 to be fastened to the upper tension risers are formed on the outside of the pontoons 102 at predetermined intervals.

As shown in FIG. 6, the ship eyepiece module 130 is formed with an eyepiece portion 131 in a space at one of four corners, and the ship enters the eyepiece portion 131 to load or unload a passenger or an article.

The pontoons 102 formed in the lower part of the ship eyepiece module 130 may be formed as an empty space as in the square module 110 or the aircraft eyepiece module 120, And each compartment may constitute an oil or gas reservoir and a ballast tank.

The multi-purpose floating platform system for offshore water according to the present invention not only produces gas at the upper part but also has a gas terminal which is a gasoline facility, an airport and a passenger terminal for logistics and passenger transportation, a marine power generation facility such as wind power generation, An airplane eyepiece module 120 on which an aircraft can berate to a platform and various vessels on which a variety of vessels can be installed, such as a villa for leisure, a marine city such as a hotel, And a plurality of marine eyepiece modules 130 capable of berthing are combined in various forms.

1 to 7, the rectangular module 110, the eyepiece eyepiece module 120, and the ship eyepiece module 130 may be configured such that the upper flat panel 101 has a width: 2 < / RTI >

As described above, the square module 110, the aircraft eyepiece module 120, and the ship low pressure module 130 are formed into a rectangular shape having a width to height ratio of 1: 2, The flat plate 101 is configured as a square-shaped module, and the flexibility of designing various types of multi-purpose floating platform systems using rectangular or square-shaped modules is increased.

For example, as shown in FIG. 8, when two square modules 110 are tangentially fixed by being tangential to each other, a square type platform 100 capable of installing various marine facilities on the upper part as shown in FIG. 9 is formed 10, the ship's eyepiece modules 130, which are formed symmetrically with respect to each other, are laterally tangent to each other, thereby forming a platform 100 (see FIG. 10) having an eyepiece portion 131, And a platform 100 in which a plurality of maritime facilities can be installed while an aircraft can berth in the sea can be provided by fastening and fixing the aircraft eyepiece module 120 and the rectangular module 110 in a lateral direction as shown in FIG. .

The platform 100 may be constructed by connecting the square module 110 with two rectangular modules 110 as shown in FIG. 13, and connecting the two modules 100 to one another to form two symmetrical ship eyepiece modules 130 as shown in FIG. A square airplane module in which one airplane eyepiece module 120 and one square module 110 are connected and a square module in which two square modules 110 are connected are continuously connected to each other for various purposes The floating platform 100 of FIG.

As shown in FIG. 15, a multi-purpose floating floating platform having a large size may be constructed by combining a plurality of modules 110, 120, and 130 together.

Although various fastening means for fastening the modules 110, 120 and 130 can be used, it is preferable to fasten the modules 110, 120 and 130 by welding.

9 to 11 illustrate the simplest platform 100 constructed by coupling two modules 110, 120 and 130. However, a plurality of modules 110, 120 and 130 may be coupled to form a large-sized marine platform 100 .

As described above, the square module 110, the aircraft eyepiece module 120, and the ship eyepiece module 130 constituting the platform all have pontoons (not shown) on the lower portion of the upper plate 101 to float the upper plate 101 on the water surface The pontoons fastened to the lower portion of the upper plate 101 of each of the modules 110, 120 and 130 are spaced apart from each other by a predetermined distance D _L , D _W from the rim of the upper plate 101 as shown in FIG. .

A space is formed between the pontoons 102 of the respective modules 110, 120 and 130 as shown in FIG. 8 by arranging them to be spaced apart from each other by a predetermined distance D _L and D _W from the rim of the upper plate 101 as shown in FIG. The flow of the algae can be smoothly performed so that the algae generator can be installed and operated not only by the structural stability but also by the algae formed between the pontoons 102.

An offshore multipurpose floating platform system according to the present invention is installed as follows.

12, a suction anchor 104 is installed on the sea floor, and the upper tension riser 105 is connected to a suction anchor 104 fixed to the sea bed and a fixture (not shown) of each module 110, 120, 103 to vertically connect and fasten the platform 100 to the seawater by forcefully submerging and fixing the platform 100 to the load draft so that the platform-based vertical movement does not occur regardless of the loading load of the platform 100.

The mooring line 106 is installed so that the mooring line 106 fastened to the bottom surface of the platform 100 is fastened to the fastener 103 so as to incline the platform 100 so that the platform 100 does not move horizontally.

Although the horizontal movement of the platform 100 may be restricted by using the mooring line 106 as described above, a thruster 107 may be installed at a lower portion of the platform 100 as shown in FIG. 12, So that the horizontal movement of the platform 100 does not occur.

In the offshore multi-purpose floating platform system of the present invention constructed as described above, the standardized square modules are connected to each other and expanded and tightened, thereby not only the gas production but also the gas terminal, the floating airport and passenger terminal, the marine power generation facility, , Marine cities, and other marine facilities of various sizes and shapes.

In addition, the offshore multi-purpose floating platform system according to the present invention can significantly reduce the damage of tsunami and can function as a breakwater when installed close to the shore because it is a floating platform based on water.

In addition, a wave generator can be installed on the pontoon side of the sea level.

In addition, the area of the pontoon can be adjusted to the displacement to cope with various loads from heavy to light weight. By forming a space between the pontoon and the pontoon of the module, Alternatively, a tidal generator may be installed and operated.

The technical idea of the present invention has been described above with reference to the embodiments.

It will be apparent to those skilled in the art that various changes and modifications may be made to the embodiments described above from the description of the present invention.

Further, although not explicitly shown or described, those skilled in the art can make various modifications including the technical idea of the present invention from the description of the present invention Which is still within the scope of the present invention.

The above-described embodiments described with reference to the accompanying drawings have been described for the purpose of illustrating the present invention, and the scope of the present invention is not limited to these embodiments.

100: Platform
101: upper plate
102: pontoon
103: Fixture
104: Suction anchor
105: upper tension riser
106: Mooring line
107: Thruster
110: square module
120: Aircraft eyepiece module
121:
130: Vessel eyepiece module
131: eyepiece

Claims (8)

A top plate 101 formed in a shape of a rectangle having a width, a width or a width of 1: 2 and a width ratio of 1: 2, and a top plate 101 spaced inwardly from the bottom of the top plate 101, And a fixture 103 formed at a predetermined interval on the outer side of the pontoon 102. The module 100 is connected to a square module 110);
An upper plate 101 having the same size as that of the rectangular module 110 is formed and an upper plate 101 having an eyepiece portion 131 formed at an edge portion of the upper plate 101 is formed, The pontoons 102 are formed at a predetermined distance from the bottom of the upper plate 101 at a lower portion of the pontoons 101 to provide a buoyancy force. A ship eyepiece module 130 configured to be in contact with the rectangular module 110 and to be connected to the eyepiece portion 131 by fastening means;
An upper plate 101 having the same size as that of the rectangular module 110 is formed and one side of the upper plate 101 is formed with an inclined surface 121 inclined downward from the upper surface of the upper plate 101, A pontoon 102 formed at a predetermined distance from the bottom of the upper plate 101 at a lower portion of the flat plate 101 to provide buoyancy to the upper plate is formed, The fastener 103 is fastened by the fastening means in contact with the rectangular module 110 or the ship eyepiece module 120 so that the amphibious plane can enter or advance into the upper flat plate 101 along the inclined surface 121 A configured aircraft eyepiece module 120; And
Fixing means coupled to the bottom surface of the square module 110, the ship eyepiece module 130 and the aircraft eyepiece module 120 to limit the vertical and horizontal movements of the respective modules; Wherein the platform is configured to include an off-the-shelf multi-purpose floating platform system.
delete delete The method according to claim 1,
Wherein the interior of the pontoon (102) is divided into a plurality of compartments, the compartments being comprised of reservoir or ballast tanks.
delete delete The method according to claim 1,
Wherein,
An upper tension riser 105 vertically connecting the suction anchor 104 and the fastener 103;
One side of the platform 100 is fixed to the sea floor and the other side is composed of a mooring line 106 which is inclined to the fixture 103 of the platform 100 so that the platform 100 is submerged in seawater up to the load draft, And to limit the horizontal movement of the water.
The method according to claim 1,
Wherein,
An upper tension riser 105 vertically connecting the suction anchor 104 and the fastener 103;
Wherein the platform is configured to restrict the vertical and horizontal movements of the platform by immersing the platform in a seawater at a load draft by providing a thruster provided at a lower portion of the platform. Multipurpose Floating Platform System.

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